Smart power source

ABSTRACT

An article having a conductive body, a magnetic diverter, and a communication device is described. The magnetic diverter is positioned on an outer surface of the conductive body. The magnetic diverter covers a substantial portion of the outer surface of the conductive body. A communication device is positioned on the outer surface of the diverter or may be recessed therein. The communication device is capable of signal coupling with a reader.

FIELD OF THE INVENTION

The present invention pertains to a portable power supplies and moreparticularly to batteries.

BACKGROUND OF THE INVENTION

Batteries are utilized in a wide variety of consumer products. Whilesome batteries are rechargeable, others are disposable. Some of thedevices that utilize rechargeable batteries provide an indication to theuser regarding the remaining energy level of the battery, e.g. cellularphones, MP3 players, powered toothbrushes, etc. However, there are somedevices which utilize rechargeable batteries that do not provide anindication to the consumer regarding the remaining energy level.Similarly, devices that utilize disposable batteries generally provideno indication to the consumer regarding the remaining energy level ofthe disposable battery. For those devices which provide no indication ofremaining energy level to the consumer, typically the only indication oflow energy levels remaining in the battery (rechargeable or disposable)is in the form of degraded performance of the device. While the consumercould feasibly remove the batteries and test them in a battery tester,this is inconvenient as each battery would have to be removed from thedevice and tested and then replaced within the device.

As such, there is a need for a device or devices as well as amethodology for allowing a consumer to check the remaining power levelsof disposable and/or rechargeable batteries while the batteries arestill within the devices which they operate.

SUMMARY OF THE INVENTION

An object having a signal communication device, the object having anouter surface, the object further comprising: an RFID tag positioned onthe outer surface of the object, the RFID tag having a resonantfrequency and an antenna; and at least one passive repeater having aresonant frequency which is the same as that of the RFID tag, the atleast one passive repeater being positioned on the outer surface of theobject adjacent to the RFID tag such that signal coupling between theRFID tag and a reader is increased by greater than about 10 percent.

A system comprising a first object and a second object, each of thefirst object and the second object having an outer surface, the systemfurther comprising: a first RFID tag positioned on the outer surface ofthe first object, the first RFID tag having a resonant frequency and anantenna; and a second RFID tag positioned on the outer surface of thefirst object, the second RFID tag having a resonant frequency which issimilar to that of the first RFID tag, wherein the first RFID tag andthe second RFID tag provide data to a reader, and wherein the secondRFID tag is positioned adjacent to the first RFID tag such that signalcoupling between the first RFID tag and a reader is increased by greaterthan about 10 percent.

An electrical component comprising: a body comprising a recess; at leastone disposable or rechargeable power source disposed within the recess,the at least one disposable or rechargeable power source comprising anRFID tag positioned on an outer surface of the at least one disposableor rechargeable power source, the RFID tag having a first resonantfrequency; a cover capable of engaging the body such that the at leastone disposable or rechargeable power source is covered when the coverengages the body; and a passive repeater disposed adjacent the RFID tag,the passive repeater having a second resonant frequency, wherein thefirst and the second resonant frequencies are similar.

An article comprising: a conductive body; a magnetic diverter positionedon an outer surface of the conductive body, the magnetic divertercovering a substantial portion of the outer surface of the conductivebody; and a communication device capable of signal coupling with areader.

BRIEF DESCRIPTION OF THE DRAWINGS

It is to be understood that both the foregoing general description andthe following detailed description describe various embodiments and areintended to provide an overview of framework for understanding thenature and character of the claimed subject matter. The accompanyingdrawings are included to provide a further understanding of the variousembodiments, and are incorporated into and constitute part of thisspecification. The drawings illustrate various embodiments describedherein, and together with the description serve to explain theprinciples and operations of the claimed subject matter.

FIG. 1 is a graphical representation showing Q factors for variousmaterials which may be utilized in a diverter.

FIGS. 2A-2D are schematic views showing a variety of configurationsregarding objects and a reader, where the objects include a magneticdiverter.

FIG. 3A is a schematic view showing an arrangement between a reader andan object having a communication device.

FIG. 3B is a schematic view showing the object of FIG. 3A including apassive repeater.

FIG. 3C is a schematic view showing the object of FIG. 3A including aplurality of passive repeaters.

FIG. 3D is a schematic view showing an embodiment where the object ofFIG. 3A includes a passive repeater and the reader of FIG. 3A included apassive repeater.

FIG. 3E is a schematic view showing another embodiment where the readerof FIG. 3A includes a passive repeater.

FIG. 4 is graphical representation showing a computer simulated model ofthe signal coupling between a first object and a first reader versus asecond object and a second reader including a passive repeater betweenthe second object and the second reader.

FIG. 5 is a graphical representation showing a computer simulated modelof the signal coupling between a first object and a first reader versusa second object and a second reader including a passive repeateradjacent the second reader.

FIG. 6 is a schematic view showing an embodiment where a plurality ofobjects is arranged with respect to a reader.

FIGS. 7A and 7B are schematic views different angles of orientationbetween an object and a reader.

FIG. 8 is a schematic view showing an embodiment where an objectcomprises multiple antennas.

FIG. 9 is a graphical representation showing a computer simulated modelof a resulting radiation pattern from the multiple antennas of FIG. 8.

FIGS. 10A and 10B are schematic views showing another embodiment of acommunication device and/or antenna of the present invention.

FIG. 11 is a schematic view showing another embodiment of acommunication device and/or antenna of the present invention.

FIG. 12A is a schematic view showing another embodiment of acommunication device and or antennas of the present invention.

FIG. 12B is a schematic view showing a first end view of thecommunication device and/or antennas of FIG. 12A.

FIG. 12C is a schematic view showing a second end view of thecommunication device and/or antennas of FIG. 12A.

FIG. 13A is a graphical representation showing measured values of anincident field for the antennas of FIG. 8.

FIG. 13B is a schematic view showing a direction for the incident fieldof FIG. 13A.

FIG. 14A is a graphical representation showing measured values of anincident field for the antennas of FIG. 8.

FIG. 14B is a schematic view showing a direction for the incident fieldof FIG. 14A.

DETAILED DESCRIPTION OF THE INVENTION

Definitions:

The following text sets forth a broad description of numerous differentembodiments of the present invention. The description is to be construedas exemplary only and does not describe every possible embodiment sincedescribing every possible embodiment would be impractical, if notimpossible, and it will be understood that any feature, characteristic,component, composition, ingredient, product, step or methodologydescribed herein can be deleted, combined with or substituted for, inwhole or part, any other feature, characteristic, component,composition, ingredient, product, step or methodology described herein.Numerous alternative embodiments could be implemented, using eithercurrent technology or technology developed after the filing date of thispatent, which would still fall within the scope of the claims.

It should also be understood that, unless a term is expressly defined inthis patent using the sentence “As used herein, the term ‘_(——————)’ ishereby defined to mean . . . ” or a similar sentence, there is no intentto limit the meaning of that term, either expressly or by implication,beyond its plain or ordinary meaning, and such term should not beinterpreted to be limited in scope based on any statement made in anysection of this patent (other than the language of the claims). No termis intended to be essential to the present invention unless so stated.To the extent that any term recited in the claims at the end of thispatent is referred to in this patent in a manner consistent with asingle meaning, that is done for sake of clarity only so as to notconfuse the reader, and it is not intended that such claim term belimited, by implication or otherwise, to that single meaning. Finally,unless a claim element is defined by reciting the word “means” and afunction without the recital of any structure, it is not intended thatthe scope of any claim element be interpreted based on the applicationof 35 U.S.C. §112, sixth paragraph.

Description:

The device of the present invention can promote the communicationbetween an object and a reader. For example, where an RFID tag isutilized, line of sight between the RFID tag and the reader may bebeneficial in aiding communication between the RFID tag and a reader.For those objects which may be orientation neutral, the position of theRFID tag may be critical to ensuring that communication may be achievedbetween the tag and the reader. For example, for a AA battery, theorientation is generally only limited by the position of the positiveand negative poles. As such, an RFID tag on the AA battery, in someinstances may be positioned such that it is on an opposite side of thebattery from the reader. This positioning may reduce the likelihood thatthe reader and the RFID tag can communicate with one another.

The communication system of the present invention may be utilized on anumber of different products. For example, the communication system ofthe present invention may be utilized on disposable and/or rechargeablebatteries. Additionally, other consumer products are contemplated. Someexamples include cans of shaving gel, cans of shaving foam, etc.Additionally, the communication system of the present invention may beutilized on devices such as remote control toys and the like. Within thecontext of disposable or rechargeable batteries, the communicationsystem of the present invention can allow a consumer to receive anindication of the remaining energy level of a disposable and/orrechargeable battery without the removal of the battery from the devicewhich it operates. Additionally, the communication system(s) of thepresent invention can allow the consumer to receive additionalinformation regarding, for example, an identification number ofarbitrary length of the battery or batteries, information about thebattery's and/or batteries' state(s), history etc., information aboutthe environment, e.g. temperature, pressure, voltage, current,information about the device in which the batteries are operating or anyother analogue information about the device and/or battery or batteries.Additionally, the communication system(s) described herein can byutilized on any cylindrical object and/or any object(s) whereomni-directional transmission is desirable.

In some embodiments, the communication system may utilize RFID (radiofrequency identification) technology. RFID technology utilizes a radiofrequency reader device that transmits an RF (radio frequency) signal ata known frequency. An RFID tag, used in RFID communication, generallycomprises an antenna and rectifier. The rectifier converts incoming RFfrequency to DC, which powers the RFID tag and other electroniccircuitry. The electronic circuitry comprises memory. When powered on,an identification number contained within the memory cells is convertedback to an RF signal and transmitted by the antenna to a reader.

The RFID tag may be positioned on and/or contained within an item ofinterest. In addition to transmitting back the identification number,the tag can also send further information stored in the memory portionof the electronic circuit. Such information may be relevant to furtherclassify the item, obtain more information about the state of the item,history etc.

In addition to information stored in the memory portion, the electroniccircuitry may have the ability to convert analogue information about theenvironment into digital data and transmit the digital data back to thereader. Such digital data could be the temperature, pressure, voltage,current, or any other analogue information about the item that the tagis attached that it is within.

In some embodiments, a transponder may be utilized to transmitinformation about the remaining energy level in a disposable orre-chargeable battery. This can be done while the disposable orre-chargeable battery is within the device and/or attached thereto.

Where the transponder provides remaining energy levels of a disposableor rechargeable battery, the transponder may comprise a sensor that iscapable of measuring battery voltage. The transponder may furthercomprise an analogue-to-digital converter to convert the measuredbattery voltage into a binary number having sufficient bit length toachieve sufficient resolution in the voltage measurement. A typicalresolution may be 4 bits; however additional bits may be utilized. Forexample, where accurate sensing is required or desired, a 16 bit lengthmay be used. In contrast, lower resolution may be utilized. For example,1 bit may be utilized in cases where a yes/no operations or sensing isdesired.

The transponder may further comprise a digital memory device to storethe converted analogue measurement value as well as the tagidentification number and any other relevant data. Moreover, thetransponder may further comprise an antenna tuned to the incoming radiofrequency of the reader to efficiently receive the incoming RF signaland to transfer an outgoing RF signal having the desired data to thereader.

Reducing Metal Body Attenuation

One of the problems associated with creating a communication device forvarious products is realized when the communication device is utilizedon conductive bodies. Free space radio propagation principles do notapply near highly conductive bodies. Additionally, antenna performanceis severely degraded when antennas are placed near metals. As such,simply placing an RFID tag on a battery or on an object with aconductive body may not accomplish the desired effect, e.g. datatransfer. Notably, this problem is not limited torechargeable/disposable batteries. For example, a can of shaving gel,foam, etc. could experience the same issues because of the conductivityof the container. In general, an RFID tag next to metallic bodydecreases signal coupling between the reader and the tag by 10×.

It has been discovered by the inventors that one way to prevent theeffects arising from metal proximity to the antenna is to prevent theelectromagnetic field from entering the metal. For example, by placing amaterial with suitable electromagnetic properties and dimensions betweenthe antenna and the metal surface the electromagnetic field may bediverted around the metallic/conductive body of the product. Theproperties of the diverter material depend on the exact metal used andthe RFID frequency. The magnetic diverter effectively isolates the tagfrom the can.

FIG. 1 shows estimated quality factors, a number suitable forcharacterizing the performance of RFID tags, as a function of thefrequency between 100 kHz and 20 MHz for different electromagneticparameters of the magnetic material, and the metal being mild steel. Ahigh quality factor generally corresponds to higher induced voltage inthe antenna of the RFID tag and better reading range.

As shown, the best estimated diversion material is free space(represented by curve 110) which achieves the highest quality factorover all. However, this proposition is unrealistic as generally spaceconstraints exist. For the curves 120, 130, and 140, the variable μ isthe magnetic permeability and the variable δ (sigma) is the electricalconductivity in Siemens per meter. The overall trend of FIG. 1 showsthat for a given μ, diverter materials having a lower electricalconductivity interfere less with signal coupling between a communicationdevice and a reader.

The magnetic material would divert the electromagnetic field away fromthe metal object if its magnetic permeability is much higher than thepermeability of the metal. And, accordingly, the eddy currents andlosses in the metal would be much reduced, and the induced voltage inthe antenna would increase. Due to this function the magnetic materialis called “magnetic diverter”. The high permeability of the magneticdiverter increases the inductance of the antenna and reduces theresonant frequency of the tag front end. But, this can be easilycompensated for by designing the antenna taking into account themagnetic properties of the diverter, or by reducing the value of theparallel capacitance in the front end LC circuit. It has beenestablished that μ>100 values assure good performance.

The electric conductivity of the material of the magnetic diverter hasto be much lower than that of metals. This is typically realized byusing ferrite-based materials. For common mild steel the relativemagnetic permeability of the diverter should be above 100. The thicknessof the magnetic diverter would depend on the magnetic permeability, andthicknesses below 100 μm are possible. In the context of disposable orrechargeable batteries, the thickness of the diverter may be constrainedsuch that the overall dimensions of the battery including the diverterare the same sizes as the standard sizes currently utilized.

As shown in FIGS. 2A-2D, an article 210 is shown comprising a conductivebody 240, a magnetic diverter 250, and a communication device 220, e.g.RFID tag. There are several different arrangements possible regardingthe communication device 220 and the magnetic diverter 250 disposed onthe article 210. In some embodiments, the diverter 250 may be placedunder the communication device 220, covering area equal or greater thanthe area of the communication device 220. In some embodiments, adiverter 250 may completely surround the conductive body 240. As shownin FIG. 2A, the article 210 may be oriented such that the communicationdevice 220 is positioned adjacent a reader 230.

As shown in FIG. 2B, it is believed that the article 210 may bepositioned such that the communication device 220 is disposed oppositethe reader 230 and still provide a sufficient signal coupling—providedof course that the magnetic diverter 250 is utilized.

As shown in FIG. 2C, it is believed that an array of articles 210A and210B may be arranged such that sufficient signal coupling can occurbetween the reader 230 and a first communication device 220A and/or asecond communication device 220B. As shown, the articles 210A and 210Bmay be constructed as described heretofore with regard to the article210. Namely, the first article 210A may comprise a conductive body 240A,a magnetic diverter 250A, and the first communication device 220A.Similarly, the second article 210B may comprise a conductive body 240B,a magnetic diverter 250B, and the second communication device 220B. Asshown, the second article 210B may be oriented such that the secondcommunication device 220B is positioned immediately adjacent to thefirst article 210A.

As shown in FIG. 2D, it is believed that even when the second article210B is oriented such that the second communication device 220B ispositioned away from the first article 210A, that sufficient signalcoupling may be achieved between the second communication device 220Band the reader 230. Similarly, embodiments are contemplated where thefirst communication device 220A is positioned adjacent the reader 230,and embodiments are contemplated where the first communication device220A is positioned away from the reader 230.

Due to the magnetic diverter 250, 250A, 250B, the magnetic flux and theinduced voltage in the communication device 220, 220A, 220B could besufficient for normal operation of the communication device 220, 220A,220B even if the antenna is positioned away from the reader 230 and onthe opposite side of the article 210, 210A, 210B.

As shown in FIGS. 2A-2D, the diverter 250, 250A, 250B, may cover asubstantial portion of an outer surface of the article. In someembodiments, the diverter 250, 250A, 250B, may cover more than about 50percent of the outer surface, more than about 60 percent, more thanabout 70 percent, more than about 80 percent, more than about 90percent, less than about 100 percent, less than about 90 percent, lessthan about 80 percent, less than about 70 percent, less than about 60percent, less than about 50 percent, or any number or any range withinor including these values.

As stated previously, the overall dimensions of an article or productmay be critical. As suggested herein, in some embodiments, the divertercan have minimal thickness. However, including the communication device,e.g. RFID tag, may prove difficult for such applications. The inventorshave discovered that the RFID tag may be recessed in the diverter. Insome embodiments, the diverter may comprise a recess. The communicationdevice, e.g. RFID tag, may be disposed in the recess. The antenna of thecommunication device may be disposed on an outer surface of thediverter.

Embodiments are contemplated where a diverter is provided to a consumerseparately from the article. For example, a consumer could obtain adiverter and fix the diverter to the article for which data was desired.The diverter may include a communication device already pre-attached orthe consumer may also obtain the communication device separately fromthe diverter and attach thereto. In some embodiments, the diverter maybe removable from the article and re-usable on subsequent articles. Forsuch embodiments, the information provided by the communication deviceto a reader may be limited. For example, if the article were adisposable or a rechargeable battery, then the communication deviceand/or battery would have to be retrofitted such that the communicationdevice could provide information regarding the remaining power level ofthe battery.

Increase of Signal Coupling

As stated above, one of the problems associated with creating acommunication device for various products is realized when thecommunication device is utilized on conductive bodies. Additionally,antenna performance is severely degraded when antennas are placed nearmetals. In general, an RFID tag next to metallic body decreases signalcoupling between the reader and the tag by 10×.

The inventors have discovered that by placing similarly tuned RFID tagsand/or passive tuned loops near the RFID tag which is desired to beread, an increase in the readout range of the desired RFID tag occurs.This solution can be implemented in a wide variety of products wheresignal communication with a reader is desired.

As shown in FIGS. 3A and 3B, a system 300 may comprise an object 310,e.g. battery, a communication device 320 and a reader 330. In operation,the reader 330, e.g. RFID reader or NFC (near fieldcommunications)-enabled smart phone, NFC enabled hand held device, couldread data from the communication device 320. The communication device320, e.g. RFID tag or other resonant RF circuit, smart sensor, etc.,could be positioned on an outer surface 350 of the object 310 ortherein. In order to increase the distance that the communication device320 can broadcast, the system 300, may comprise a tuned repeater 340.The repeater 340 may be positioned on the object 310, or may bepositioned adjacent to the object 310.

In some embodiments, the communication device 320 may comprise an RFIDtag. In such embodiments, the RFID tag may have a resonant frequency andantenna. For such embodiments, where a repeater 340 is included, therepeater 340 may be tuned similar to the RFID tag. For example, therepeater 340 may have a second resonance frequency which is similar tothat of the first resonance frequency.

The tuned repeater 340 can promote an increased amount of energy coupledinto the reader 330 by the communication device 320 even when thecommunication device 320 is facing opposite the reader 330. In general,the amount of energy coupled into a reader decreases with increaseddistance from the communication device 320. However, with the inclusionof a repeater tuned to the same frequency as the communication device320, e.g. RFID tag, and the reader 330, the amount of energy coupledbetween the communication device 320 and the reader 330 increases. Theincrease of signal coupling between the communication device 320 and thereader 330 with the utilization of the passive repeater 340 is discussedhereafter with regard to FIGS. 4 and 5.

Referring now to FIG. 3C, in some embodiments, a system 300C maycomprise the object 310, e.g. battery, the communication device 320 andthe reader 330. In operation, the reader 330 could read data from thecommunication device 320. The communication device 320 may be positionedon an outer surface 350 of the object 310 or therein. In contrast withthe system 300, the system 300C, in order to increase the distance thatthe communication device 320 can broadcast, the system 300C, maycomprise a plurality of repeaters 340, 342. The repeaters 340, 342 maybe positioned on the object 310, or may be positioned adjacent to theobject 310. While only two repeaters 340 and 342 are shown, embodimentsare contemplated where more than two repeaters may be utilized.

For those embodiments utilizing multiple repeaters, e.g. system 300Dshown in FIG. 3D, at least one of the repeaters, e.g. 342D, may bepositioned adjacent to the object. The system 300D may comprise theobject 310, e.g. battery, the communication device 320 and the reader330. In operation, the reader 330 could read data from the communicationdevice 320. The communication device 320 could be positioned on an outersurface 350 of the object 310 or therein. The system 300D may furthercomprise a first repeater 340D and a second repeater 342D. The firstrepeater 340D may be positioned on the outer surface 350 of the object310 similar to the communication device 320. The second repeater 342Dmay be positioned adjacent to the object 310. For example, as shown, thesecond repeater 342D may be positioned on the reader 330, e.g. betweenthe first repeater 340D and the reader 330. Alternatively, it isbelieved that the second repeater 342D may be placed adjacent to thereader 330 to provide a similar effect of increasing signal couplingbetween the communication device 320 and the reader 330.

Referring to FIG. 3E, embodiments are contemplated where a system 300Ecomprises the object 310, e.g. battery, the communication device 320 andthe reader 330. In operation, the reader 330 could read data from thecommunication device 320. The communication device 320 could bepositioned on an outer surface 350 of the object 310 or therein. Thesystem 300E may further comprise a repeater 340E. The repeater 340E maybe positioned adjacent the object 310, e.g. between the communicationdevice 320 and the reader 330. Alternatively, it is believed that therepeater 340D may be placed adjacent to the reader 330 to provide asimilar effect of increasing signal coupling between the communicationdevice 320 and the reader 330.

Additional embodiments are contemplated where a plurality of repeatersare provided on the object as well as adjacent thereto, e.g. on thereader. Other embodiments are contemplated where the reader comprises aplurality of repeaters while the object comprises the communicationdevice 320.

Referring back to FIG. 3B, for those embodiments utilizing a singlerepeater or a plurality of repeaters which are positioned on the outersurface 350 of the object 310, the repeater(s) may be spaced from thecommunication device 320 and/or the antenna thereof such that therepeater does not physically contact the communication device 320 and/orantenna. A gap 375 may be between the repeater(s) and the communicationdevice 320. In some embodiments, the gap 375 may be greater than about 1mm, greater than about 5 mm, greater than about 10 mm, greater thanabout 20 mm, greater than about 30 mm, greater than about 40 mm, greaterthan about 50 mm, greater than about 60 mm, greater than about 70 mm,less than about 75 mm, less than about 70 mm, less than about 60 mm,less than about 50 mm, less than about 40 mm, less than about 30 mm,less than about 20 mm, less than about 10 mm, or any value and/or anyrange including or within the values provided.

As shown in FIGS. 3A-3E, the repeaters 340, 340D, 342 and/or thecommunication device 320 may conform to the outer surface 350 of theobject 310. The repeaters may cover a substantial portion of the outersurface 350 of the object 310 and/or a substantial portion of theperiphery of the object. The repeaters collectively may cover at leastabout 20 percent, at least about 30 percent, at least about 40 percent,at least about 50 percent, at least about 60 percent, at least about 70percent, at least about 80 percent, at least about 90 percent and/orless than about 90 percent, less than about 80 percent, less than about70 percent, less than about 60 percent, less than about 50 percent, lessthan about 40 percent, or any number or any range including or withinthe above values. Similarly, the communication device 320 may cover asubstantial portion of the outer surface 350 of the cylindrical object310 and/or a substantial portion of the periphery of the object asdescribed above with regard to the repeaters.

It is believed that by conforming the communication device 320 and/orthe repeaters to the outer surface 350 of the object, the signalcommunication between the communication device 320 and the reader 330can be provided at a variety of angles. For example, where thecommunication device has its face oriented in a direction away from thereader, the inclusion of repeaters or by conforming the communicationdevice to the periphery of the object, signal communication between thereader and the communication device may still be able to be established.

Regarding the periphery of the object, the coverage described above isin the context of the periphery of the cross section taken generallyperpendicular to a long dimension of the object.

As mentioned previously, the inclusion of the repeater is believed toincrease the signal coupling between the communication device 320 andthe reader 330. FIG. 4 graphically illustrates the differences in signalcoupling between systems utilizing no repeater and those systemsutilizing a passive repeater between the communication device and thereader.

As shown in FIG. 4, curve 470 shows the computer simulated model of thesignal coupling between a communication device and a reader that arepositioned 64 mm apart from one another. At the peak of curve 470, thesignal coupling is approximately 2.0 percent. Curve 480 represents thesignal coupling for those embodiments that utilize at least one repeaterpositioned between the communication device and the reader. In contrastto the curve 470, at the peak of curve 480 the signal coupling is about3.7 percent. As such, it is believed that the inclusion of the repeaterbetween the communication device and reader can increase the signalcoupling by about 85 percent. The presence of the passive repeater canchange the resonant frequency of nearby resonators and require finesystem-level tuning to keep all circuits in resonance. As such, the peakof the curve 480 may be offset from the peak of curve 470.

Any suitable percentage increase in signal coupling may be realized. Forexample, in some embodiments, the increase in signal coupling may begreater than about 1 percent, greater than about 5 percent, 10 percent,greater than about 20 percent, greater than about 30 percent, greaterthan about 40 percent, greater than about 50 percent, greater than about60 percent, greater than about 70 percent, greater than about 80percent, greater than about 85 percent, greater than about 90 percent,greater than about 100 percent, less than about 90 percent, less thanabout 85 percent, less than about 80 percent, less than about 70percent, less than about 60 percent, less than about 50 percent, lessthan about 40 percent, less than about 30 percent, less than about 20percent, or any number or any range including or within the valuesprovided above.

FIG. 5 graphically illustrates the differences in the computer simulatedmodel of the signal coupling between systems utilizing no repeater andthose systems utilizing a passive repeater adjacent the reader.

As shown in FIG. 5, curve 570 shows the signal coupling between acommunication device and a reader that are positioned apart from oneanother. At the peak of curve 570, the signal coupling is approximately4.00 percent. Curve 580 represents the signal coupling for thoseembodiments that utilize at least one repeater positioned adjacent thereader. In contrast to the curve 570, at the peak of curve 580 thesignal coupling is about 4.40 percent. As such, the inclusion of therepeater between the communication device and reader is believed toincrease the signal coupling by about 10 percent. In some embodiments,this configuration may yield lower signal coupling increases or higher,e.g. greater than 1 percent, greater than 2 percent, greater than 3percent, greater than 5 percent, greater than about 7 percent, greater10 percent, greater than about 12 percent, greater than 15 percent, lessthan about 12 percent, less than about 10 percent, less than about 9percent, less than about 8 percent, less than about 7 percent, less thanabout 5 percent, less than about 3 percent, less than about 2 percent orany number or any range including or within these values. Similar to thecurves shown in FIG. 4, the inclusion of the passive repeater can shiftthe peak of curve 580 with respect to the peak of curve 570.

Referring to FIG. 6, it has been discovered that the use of multiplecommunication devices, e.g. RFID tags, adjacent one another cansimilarly increase the signal coupling between a desired communicationdevice and a reader. For example, a system 600 may comprise a pluralityof objects, e.g. 610A, 610B, 610C, 610D, 610E, and 610F, and a reader630. In some embodiments, each of the objects, e.g. 610A, 610B, 610C,610D, 610E, and 610F, may comprise a communication device, e.g. 620A,620B, 620C, 620D, 620E, and 620F, respectively. Each of thecommunication devices may be positioned on an outer surface of itsrespective object. In operation the reader 630 would transmit signals toand from at least one of the communication devices, e.g. 620A, 620B,620C, 620D, 620E, and 620F.

Each of the communication devices, e.g. 620A, 620B, 620C, 620D, 620E,and 620F, may have resonance frequencies which are similar to oneanother.

Because an increase in signal coupling can be achieved with theutilization of communication devices, communication devices may beutilized in the previous embodiments including repeaters. Due to costreasons, replacing every repeater with a communication device may beexpensive to achieve. However, embodiments, are contemplated where asystem comprises a plurality of communication devices and at least onerepeater. The plurality of communication devices may individually beconformed on the outer surface of a respective object where the objectsare positioned adjacent one another. Additionally, at least onecommunication device may be positioned between at least one of theobjects of the plurality of objects and the reader.

Embodiments are contemplated where the objects are disposable orrechargeable batteries. For such embodiments and all the embodimentsdescribed herein, the proposed communication device may comprise anelectronic sensor capable of measuring battery voltage, ananalogue-to-digital converter which can covert the measured batteryvoltage into a binary number, a memory device, front end circuitry, andan antenna.

The analogue-to-digital converter should have sufficient bit length toconvert the measured battery voltage into a binary number with the samebit length to achieve sufficient resolution in the voltage measurement.The memory device may be utilized to store the converted analoguemeasurement value as well as the tag identification number and any otherrelevant data, e.g. history of the object, history of use of the object,etc.

The front end circuitry may be utilized to convert the incoming signalfrom the reader into DC current to power the communication device. Forsuch embodiments, the communication device may be passive. Specifically,where the communication device derives power indirectly from RF signalsfrom a reader or from another source, the communication device ispassive. In contrast, where the communication device is in electricalcommunication with a power source, the power source not being the datasignal, the communication device is active. The communication device forutilization in any of the embodiments described herein may be passive oractive or hybrid (battery assisted to continuously “listen” withoutbeing powered by the reader for improved range of operation). In thecase of disposable or rechargeable batteries, passive communicationdevices are attractive as they do not require power from the disposableor rechargeable battery. The front end circuitry can further transmitthe contents of the memory back to the reader in a pre-defined protocol.

The antenna may be tuned to the incoming radio frequency to efficientlytransfer the incoming signal, e.g. radio frequency, into the front endcircuitry and to re-radiate the same signal modulated with the contentsof the digital data back to the reader.

For those embodiments where the objects are disposable or rechargeablebatteries, determining remaining power levels of the batteries isfacilitated for the consumer. For example, with the utilization ofrepeaters and/or communication devices as described heretofore, thesignal coupling between the reader and the object is increased.

As an example in the increase in signal coupling, in some embodiments,the system may comprise an electronic device. The electronic device maycomprise a recess in which at least one object, e.g. a disposable orrechargeable battery, is positioned. By utilizing the repeater orcommunication device as described heretofore, a consumer may be able toobtain information regarding the remaining energy in the disposable orrechargeable battery while the disposable or rechargeable battery isstill within the electronic device. As an example, batteries in a remotecontrol toy may utilize the invention(s) described herein. The batteriesmay be positioned in a recess and equipped with communication devices. Adoor for sealing the recess and the batteries may comprise a separatecommunication device and/or a repeater. This can allow the user todetermine the remaining service life of the battery while stillpositioned within the electronic device.

Additional information may be provided to the consumer. For example,data on the history of the battery, e.g. the last measured voltage ofthe battery, date and time of the measured voltage. This may bebeneficial in providing a projected remaining lifetime of therechargeable or disposable batteries.

The electronic device may comprise a cover which engages with a portionof the electronic device to at least partially cover the object, e.g.disposable/rechargeable battery. In accordance with the embodimentsdescribed heretofore, the cover may comprise a repeater or acommunication device in order to increase the signal coupling betweenthe disposable or rechargeable battery and the receiver. For thoseembodiments, where the cover comprises a communication device, thecommunication device may provide additional information to the consumerregarding the electronic device. The reader may be programmed tocalculate and display remaining runtime based on the device loadinformation. Embodiments are contemplated where the repeater or thecommunication device comprised by the cover is a sticker which is laterattached to the cover by the consumer. Similarly, embodiments arecontemplated where the repeater or the communication device is a stickerand is applied to the receiver.

As described previously, the repeaters may comprise passive loops tunedsimilarly to the communication devices. In some embodiments, therepeaters may comprise multiple communication devices, e.g. RFID tags.

Rotational Diversity

An additional issue which may occur is due to rotational orientation ofthe object/article. Generally, the configuration of the communicationdevice is intended for readout with the receiver in such a positionwhich is parallel with the antenna. Readout from the ends of the objectmay not be possible. Similarly, readout may not be possible when thereader is parallel to the object but perpendicular to the tag antenna.

Typically there is an imbalance in the signal magnitude between the twosides of the object. As shown in FIG. 7A, a peak of the radiationpattern is when a reader 730 is facing the communication device 720. Incontrast, as shown in FIG. 7B, the radiation pattern reduces to zero inwhen the reader 730 is rotated perpendicular to the communication device720. Additionally, the readout range when the communication device 720is exactly on the opposite side is significantly lower compared to thecase when the antennas are facing each other.

As shown in FIG. 8, a system 800 may comprise a receiver 830, and acommunication device 820. The communication device 820 may comprise afirst antenna 821A and a second antenna 821B. The signal from the secondantenna 821B may go through a phase shifting circuit (RC circuit) toshift the voltage of the second loop by 90 degrees to bring the voltagesin phase to the input of an analogue adder circuit. The resultingvoltage is applied to the input of an RFID transceiver 815. In suchembodiments, the signal from the first antenna 821A may not go throughthe phase shifting circuit.

The antenna 821 may be provided with additional portions for enhancingsignal coupling at additional angles. For those embodiments includingadditional portions, a phase shifting network may also be included forcombining the signals from all antennae in phase. The phase shiftingcould be done by any suitable means. For example, the phase shiftingcould be done by a passive RLC network.

The induced signal in the 2-antenna configuration as a function of theangle θ between the plane of the reader antenna and the plane of one ofthe communication device antennae 821 is V=A₀(sin θ+cos θ), and neverdrops to zero. A resulting radiation pattern calculated in comparison tothe calculated radiation pattern of a single antenna and the unit circleis given in FIG. 9.

As shown in FIG. 9, an arcuate line 940 shows the computer simulatedmodel of a radiation pattern utilizing the first antenna 821A and thesecond antenna 821B as described above. The arcuate line 950 shows thecalculated radiation pattern for a single antenna.

Embodiments are contemplated where the reader comprises an antennaconstructed similar to the antenna 821. Namely, the antenna of thereader may comprise a first portion and a second portion which areoffset from each other by a particular angle, e.g. 90 degrees. Also,embodiments are contemplated where the object comprises the antenna 821as described heretofore and the reader comprises an antenna configuredsimilar to the antenna 821. For those embodiments where the readercomprises an antenna configured similar to the antenna 821, additionalportions may be utilized in the antenna 821 and/or the antenna of thereader.

The embodiments described with regard to FIGS. 8 and 9 can provideincreased signal coupling between the reader and the object at angles oforientation of the reader which were heretofore problematic.

Measurements based upon a prototype using multiple antennas as describedin FIGS. 8 and 9 are provided with regard to FIGS. 13A and 13B and 14Aand 14B. Regarding 13A and 13B, measurements of the incident field weretaken with respect to the field having the direction 1380 about anobject 1310. A plot 1360 shows the measured values at various angleswith regard to the object 1310. In contrast plot 1340 shows thecalculated values. As shown for both plots 1340 and 1360, in the areabetween 180 degrees and 270 degrees, the measured values differ from thecalculated values by a larger margin than anywhere else on FIG. 13A.However, the radiation pattern is fairly uniform about the object 1310in the direction 1380. So, the embodiments described with regard toFIGS. 8 and 9 can produce rotational diversity about the object 1310 inthe direction 1380.

Regarding, FIGS. 14A and 14B, measurements of the incident field weretaken with respect to the field having the direction 1480 about anobject 1310. A plot 1460 shows the measured values at various angleswith regard to the object 1310. In contrast plot 1440 shows thecalculated values. As shown for both plots 1440 and 1460, in the areabetween 270 degrees and 0 degrees, the measured values differ from thecalculated values by a larger margin than anywhere else on FIG. 14A.However, similar to the plot shown in FIG. 13A, the radiation pattern isfairly uniform about the object 1310 in the direction 1480. So, theembodiments described with regard to FIGS. 8 and 9 can producerotational diversity about the object 1310 in the direction 1480.

Rotational Orientation of the Object:

Additional measures can be taken to ensure that the range of null anglesis reduced. In general, the readout range between any two loop antennasis not uniform for all angular positions of the two antennas withrespect to each other. There are some angles when the readout isimpossible due to the lack of magnetic coupling. Such angles are termed“nulls”.

As described previously, a rectangular loop antenna may be bent toconform to the outer periphery of the object; however, in thisconfiguration the conformed rectangular antenna inherently prefers oneside of the object to the other when a reader is positioned in parallelto the cylinder and rotated around the cylinder axis (equivalent to thereader being fixed and the cylinder being rotated around its own axis).As such, when the rectangular antenna is facing the receiver, signalcoupling is good. However, when the rectangular antenna is facing awayfrom the receiver, the signal coupling between the rectangular antennaand the receiver is decreased. As such, the rotation of the object maycause nulls to occur.

As discussed previously, the utilization of repeaters may alleviate thisproblem. The repeaters are discussed in detail with regard to FIGS.3A-6.

Additionally, in an effort to increase the symmetry of the signalmagnitude between the two sides, the inventors have devised a uniqueconfiguration for a communication device. The configuration may comprisethe communication device or may comprise only portions of thecommunication device. For example, in some embodiments, the uniqueconfiguration could comprise the antenna of the communication device.For the sake of clarity reference will be made to the communicationdevice and will encompass configurations of the entire communicationdevice or portions thereof, e.g. antenna.

The proposed communication device can increase the symmetry of thesignal magnitude between the two sides of the object and 360 degreesaround it. As shown in FIGS. 10A and 10B, where an object 1010 has acylindrical shape, a communication device 1020 may be provided. Thecommunication device 1020 may comprise a first portion 1020A disposedadjacent to a first end 1080 of the object 1010 and a second portion1020B disposed adjacent to a second end 1090. The first portion 1020Aand the second portion 1020B may be longitudinally offset. The firstportion 1020A may extend about the circumference (outer periphery) ofthe object 1010 for about 180 degrees. In contrast, the second portion1020B may extend about the circumference (outer periphery) of the object1010 for about 180 degrees. The 180 degrees covered by the first portion1020A may correspond to zero degrees to 180 degrees while the 180degrees covered by the second portion 1020B may correspond to 180degrees to 360 degrees. As such the 180 degree sweep of the object 1010by the first portion 1020A may be opposite the 180 degree sweep of theobject 1010 by the second portion 1020B.

The configuration of the communication device 1020 of FIGS. 10A and 10Bcan shift the null angle which helps reading from the side at 90 deg,e.g. when the reader is perpendicular to the antenna. The nulls may beshifted to about 45-60 deg. which is an inconvenient angle, and theconsumers are not expected use it.

Although FIGS. 10A and 10B show the object 1010 as a cylinder, thecommunication device 1020 described above may be applied to any objectof any size and/or shape. For example, a 9 volt battery is typicallynon-cylindrical and instead has more of a rectangular cross section. Thecommunication device similar to the communication device 1020 describedabove may be applied to the 9 volt battery in a similar manner. As shownin FIG. 11, an object 1110 may be non-cylindrical and still utilize acommunication device 1120. Again, for the sake of clarity, thecommunication device 1120 may be configured similar to the communicationdevice 1020 or the antenna of the communication device 1120 may beconfigured as described heretofore regarding the antenna of thecommunication device 1020.

The antenna 1120 may comprise a first portion 1120A and a second portion1120B. The first portion 1120A may be disposed on a first face 1150 anda portion of sides faces 1152. The second portion 1120B may be disposedon a second face 1160 and a portion of the side faces 1152.

For those objects which are non-cylindrical, the outer circumference ofthe object can be used approximate the degrees of sweep covered by anantenna or portion thereof. As an example, referring back to FIG. 11, aface 1175 of the object 1110 may be encircled and thereby used toapproximate the angle of sweep covered by the antenna(s) or portionsthereof.

It is believed that utilization of the antenna 1020 and 1120 describedherein may provide a more balanced signal radiation pattern.Additionally, utilization of the antennas 1020 and 1120 may allow areader to be adjacent an end of the object, e.g. 1010, 1110, and stillread the data from the communication device.

The design of the antennas and/or communication devices described hereinmay influence greatly the areas where signal reception by the reader isdifficult. While the maximum readout range depends on the transmittedpower, in part, the position of the nulls are entirely dependent on thegeometry and physical arrangement of the antennas, and is completelyindependent of other electrical parameters such as power, inductance,resonance frequency etc.

The curved sides of the tag antenna closing on the opposing sides of thecylinder can provide readout on the ends of the object as opposed to aconventional antenna. However, depending on the design of theantenna(s), the angular position of nulls can be changed by changing theso called “aspect ratio” of the antenna(s). The aspect ratio is definedby the ratio of the cylinder diameter D to the length of the antenna l,i.e. D/l. The diameter of the cylinder is a given parameter depending onthe size of the object, but the ratio can be changed by varying thelength of the antenna within the constraints of the object length. For asituation where D/l approaches zero, an infinitely long antenna, the tagantenna will approximate a planar loop antenna and the angular locationof the nulls will approach the ends of the object. In contrast, l may beforced to approach zero, hence making D/l approach infinity. For suchcases the antenna may approximate a loop antenna wrapped around theobject. In such a case, the nulls will be rotated by 90 degrees to thecylinder side walls. It is possible to move the position of the nulls toany position in between these two limits by varying the length of theantenna, depending on where, in the present application, “natural” or“intuitive” readout angles are considered to be.

The principle of shifting nulls of the antenna radiation pattern to anydesirable angular position through the adjustment of the antennageometry would be applicable to any number of antenna and device typesand not limited to cylindrical objects.

Embodiments are contemplated where the objects are configured with anantenna which is custom tailored for its end use. For example, where thereader is expected to read from the ends of the object, a first antennaconfigured to allow reading from the ends of the object may be provided.Where the reader is expected to read from the sides of the object, asecond antenna configured to allow reading from the sides of the objectmay be provided. So, where the object is an AA battery, a first AAbattery may comprise a first antenna allowing reading from the ends ofthe AA battery. Additionally, a second AA battery may comprise a secondantenna allowing reading from the sides of the second AA battery.

A plurality of first AA batteries may be packaged together. A pluralityof second AA batteries may be packaged together. Additionally, in someembodiments, a first AA battery and a second AA battery may be packagedtogether or a plurality either or both.

Embodiments are contemplated where an object comprises a communicationdevice which incorporates several of the aspects described herein. As anexample, an object may comprise a communication device having aconfiguration as shown in FIG. 12A. A communication device 1220 and/orantenna shown in FIG. 12A may be configured similar to the communicationdevices 1020 and 1120 shown in FIGS. 10 and 11. As such, thecommunication device 1220 may comprise an antenna 1221 having a firstportion 1221A and a second portion 1221B. The first portion 1221A andthe second portion 1221B may be oppositely positioned from oneanother—both on opposite ends of the object but also on opposite faces.

The communication device 1220 may further comprise a second antenna 2420having a first portion 2420A and a second portion 2420B. The firstportion 2420A and the second portion 2420B may be oppositely positionedfrom one another—both on opposite ends of the object but also onopposite faces.

FIGS. 12B and 12C show the overlap between the first antenna 1221 andthe second antenna 2420. FIG. 12B shows the communication device 1220when viewed from a first end 1280 looking toward a second end 1290. Thefirst portion 1221A of the first antenna 1221 may cover about 180degrees of a cylindrical object. The 180 degrees may be in a firstquadrant I and a fourth quadrant IV. Similarly the first portion 2420Aof the second antenna may cover about 180 degrees of a cylindricalobject. The 180 degrees may be in a third quadrant III and the fourthquadrant IV. The first portion 1221A of the first antenna 1221 and thefirst portion 2420A of the second antenna 2420 may overlap with oneanother in the fourth quadrant IV, e.g. section 2021.

The second portion 1221B of the first antenna 1221 may cover about 180degrees of a cylindrical object. The 180 degrees covered by the secondportion 1221B of the first antenna may be opposite that of the firstportion 1221A. For example, the 180 degrees covered by the secondportion 1221B may be in a second quadrant II and the third quadrant III.Similarly, the second portion 2420B of the second antenna 2420 may coverabout 180 degrees of a cylindrical object. The 180 degrees covered bythe second portion 2420B may be opposite that of the first portion2420A. For example, the 180 degrees covered by the second portion 2420Bmay be in the first quadrant I and the second quadrant II. The secondportion 1221B of the first antenna 1221 and the second portion 2420B ofthe second antenna 2420 may overlap with one another in the secondquadrant II, e.g. section 2022.

For most objects, the first antenna 1221 and the second antenna 2420 maybe positioned such that the first antenna 1221 is positioned within thesecond antenna 2420 or vice versa. Where space constraints are an issue,the first antenna 1221 and the second antenna 2420 may be positionedsequentially such that the first portion 1221A of the first antenna 1221is positioned directly behind the first portion 2420A of the secondantenna 2420. In some embodiments, the antennas described in FIGS.12A-12C may be printed on both sides of a flexible substrate. This canhelp minimize the overall dimensions added to the object.

For the embodiments described in FIGS. 12A-12C, the communication device1220 may comprise a phase shifter to bring the voltages in phase betweenthe first antenna 1221 and the second antenna 2420.

Several embodiments have been provided heretofore which can provide forincreased signal coupling between a communication device and a reader.Embodiments are contemplated where an article comprises a communicationdevice configured as described in FIGS. 8-9. In such embodiments, thearticle may be comprised by a system which includes a reader.Furthermore, in such embodiments, the article and/or the reader maycomprise a repeater. Alternatively, the system may comprise a repeaterpositioned between the article and the reader. Additionally, where thearticle comprises a conductive body, the article may further comprise adiverter. In such embodiments, the communication device may be disposedon an outer surface of the diverter or adjacent thereto.

Embodiments are contemplated where an article comprises a communicationdevice configured as described with regard to FIGS. 10A and 10B. In suchembodiments, the article may be comprised by a system which includes areader. Furthermore, in such embodiments, the article and/or the readermay comprise a repeater. Alternatively, the system may comprise arepeater positioned between the article and the reader. Additionally,where the article comprises a conductive body, the article may furthercomprise a diverter. In such embodiments, the communication device maybe disposed on an outer surface of the diverter or adjacent thereto.

Embodiments are contemplated where an article comprises a communicationdevice configured as described with regard to FIGS. 12A-12C. In suchembodiments, the article may be comprised by a system which includes areader. Furthermore, in such embodiments, the article and/or the readermay comprise a repeater. Alternatively, the system may comprise arepeater positioned between the article and the reader. Additionally,where the article comprises a conductive body, the article may furthercomprise a diverter. In such embodiments, the communication device maybe disposed on an outer surface of the diverter or adjacent thereto.

Embodiments are contemplated where an article comprises a system havingan article and a reader. The article may comprise a communication deviceconfigured as described in any of the embodiments herein. In suchembodiments, the article and/or the reader may comprise a repeater.Alternatively, the system may comprise a repeater positioned between thearticle and the reader. Additionally, where the article comprises aconductive body, the article may further comprise a diverter. In suchembodiments, the communication device may be disposed on an outersurface of the diverter or adjacent thereto.

Embodiments are contemplated where an article comprises a communicationdevice configured as described in any of the embodiments herein. Thearticle may be comprised by a system which includes a reader. Where thearticle comprises a conductive body, the article may further comprise adiverter. In such embodiments, the communication device may be disposedon an outer surface of the diverter or adjacent thereto.

Wireless Charging

A RFID link is in essence a wireless resonant energy transfer link,utilizing the transferred energy to power a tag containing a specificidentification number. The tag may optionally include various sensorsand able to communicate its identification and any sensor informationback to the reader device through the use of the same media. All theinventions listed herein are applicable to wireless resonant energytransfer. Hence, the embodiments described herein allow for anomni-directional wireless charging system for battery charging as wellas for RFID communications. Specifically, the embodiments describedherein improve the efficiency of charging. For example, it is believedthat the utilization of the diverter increases signal coupling betweenthe communication device and the reader and/or charging device by about10 times above those systems which do not utilize a diverter. Similarly,it is believed that the utilization of a repeater in a system increasesthe signal coupling between the communication device and the readerand/or charging device by about 20 percent to about 30 percent. Also,based on the embodiments described herein, it may be possible to achievewireless charging of batteries without their removal from thehousing/case in which they reside.

The dimensions and values disclosed herein are not to be understood asbeing strictly limited to the exact numerical values recited. Instead,unless otherwise specified, each such dimension is intended to mean boththe recited value and a functionally equivalent range surrounding thatvalue. For example, a dimension disclosed as “40 mm” is intended to mean“about 40 mm.”

Every document cited herein, including any cross referenced or relatedpatent or application, is hereby incorporated herein by reference in itsentirety unless expressly excluded or otherwise limited. The citation ofany document is not an admission that it is prior art with respect toany invention disclosed or claimed herein or that it alone, or in anycombination with any other reference or references, teaches, suggests ordiscloses any such invention. Further, to the extent that any meaning ordefinition of a term in this document conflicts with any meaning ordefinition of the same term in a document incorporated by reference, themeaning or definition assigned to that term in this document shallgovern.

While particular embodiments of the present invention have beenillustrated and described, it would be obvious to those skilled in theart that various other changes and modifications can be made withoutdeparting from the spirit and scope of the invention. It is thereforeintended to cover in the appended claims all such changes andmodifications that are within the scope of this invention.

What is claimed is:
 1. An article comprising: a conductive body; amagnetic diverter positioned on an outer surface of the conductive body,the magnetic diverter covering a substantial portion of the outersurface of the conductive body; and a communication device; wherein thecommunication device comprises at least one of (i) an RFID tag, (ii) aresonant RF circuit, and (iii) a smart sensor; wherein the communicationdevice comprises a first antenna and a second antenna, the secondantenna being in electrical communication with a phase shifting circuit,wherein the phase shifting circuit shifts the voltage of the secondantenna by about 90 degrees, wherein the first antenna has a firstportion and a second portion, and wherein the first portion ispositioned on an outer surface of the diverter and encloses the articlein a sweep of about 180 degrees and wherein the second portion islongitudinally offset from the first portion and encloses the article ina sweep of about 180 degrees which is opposite the sweep of the firstportion.
 2. The article of claim 1, wherein the magnetic divertercomprises a recess, and wherein the communication device is disposedwithin the recess.
 3. A system comprising the article of claim 1 and areader capable of signal coupling with the communication device, thesystem further comprising a passive repeater.
 4. The system of claim 3,wherein the passive repeater is positioned between the article and thereader.
 5. The system of claim 3, wherein the article comprises thepassive repeater.
 6. The system of claim 3, wherein the reader comprisesthe passive repeater.
 7. The article of claim 1, wherein the secondantenna has a first portion and a second portion, wherein the firstportion is positioned on an outer surface of the diverter and enclosesthe article in a sweep of about 180 degrees and wherein the secondportion is longitudinally offset from the first portion and encloses thearticle in a sweep of about 180 degrees which is opposite the sweep ofthe first portion.
 8. The article of claim 1, wherein the first antennahas a first portion enclosing the article in a sweep of about 180degrees and a second portion longitudinally offset from the firstportion and enclosing the article in a sweep of about 180 degrees whichis opposite the sweep of the first portion, and wherein the secondantenna has a first portion enclosing the article in a sweep of about180 degrees and a second portion longitudinally offset from the firstportion and enclosing the article in a sweep of about 180 degrees whichis opposite the sweep of the first portion.
 9. The article of claim 8,wherein the first antenna first portion and the second antenna firstportion are offset from one another by about 90 degrees.
 10. The articleof claim 8, wherein the first antenna second portion and the secondantenna second portion are offset from one another by about 90 degrees.